Introduction

We know how to add two integers using a perfectly simple and useful algorithm learned from school or even earlier. This is perhaps one of the very first techniques we learn in mathematics. However we need to answer few questions. First of all do computers use the same technique, since they use binary representation of numbers? Is there a faster algorithm used by computers? What about boundaries and large integers?

Overview

Let’s start by explaining how we humans add two numbers. An important fact is that by adding two single-digit numbers we get at most two digit number. This can be proven by simply realizing that 9+9 = 18. This fact lays down in the way we add integers. Here’s how.

We just line-up the integers on their right-most digit and we start adding them in a column. In case we got a sum greater than 9 (let’s say 14) we keep only the right-most digit (the 4) and the 1 is added to the next sum.

Thus we get to the simple fact that by adding two n-digit integers we can have either an n-digit integer or a n+1 digit integer. As an example we see that by adding 53 + 35 (two 2-digit integers) we get 88, which is again 2-digit integer, but 53 + 54 result in 107, which is 3 digit integer.

That fact is practically true, as I mentioned above, for each pair of n-digit integers.

What about binary numbers?

In fact binaries can be added by using the exact same algorithm. At the example below we add two integers represented as binary numbers.

As a matter of fact this algorithm is absolutely wonderful, because it works not only on decimals and binaries but in any base B.

Of course computers tend to perform better when adding integers that “fit” the machine word. However as we can see later this isn’t always the case and sometimes we need to add larger numbers that exceed the type boundaries.

What about big integers?

Since we know how to add “small” integers, it couldn’t be so hard to apply the same algorithm on big integers. The only problem is that the addition will be slower and sometimes (done by humans) can be error prone.

So practically the algorithm is the same, but we can’t just put a 1 billion integer into a standard computer type INT, right? That means that the tricky part here is the way we represent integers in our application. A common solution is to store the “big” integer into an array, thus each digit will be a separate array item. Then the operation of addition will be simple enough to be applied.

Complexity

When we talk about an algorithm that is so well known by every human being (or almost every) a common question is “is there anything faster” or “do computers use a different algorithm”. The answer may be surprising to someone, but unfortunately that is the fastest (optimal) algorithm for number addition.

Practically there’s nothing to optimize here. We just read the two n-digit numbers (O(n)), we apply “simple” addition to each digit and we carry over the 1 from the sums greater than 9 to the next “simple” addition. We don’t have loops or any complex operation in order to search for an optimization niche.

Application

It’s strange how often this algorithm is asked on coding interviews. Perhaps the catch is whether the interviewed person will start to look for a faster approach?! Thus is cool to know that this algorithm is optimal.

Sometimes we may ask ourselves why we humans use decimals. It’s considered because we have 10 fingers on our hands and this is perhaps true.

An interesting fact though, is that the Mayas (who barely predicted the end of the world a couple of weeks ago) used a system of a base 20. That is logical, since we have not 10, but total of 20 fingers considering our legs.

Finally, this algorithm may seem to easy to be explained but it lays down in more complex algorithms.

Introduction

Each natural number that is divisible only by 1 and itself is prime. Prime numbers appear to be more interesting to humans than other numbers. Why is that and why prime numbers are more important than the numbers that are divisible by 2, for instance? Perhaps the answer is that prime numbers are largely used in cryptography, although they were interesting for the ancient Egyptians and Greeks (Euclid has proved that the prime numbers are infinite circa 300 BC). The problem is that there is not a formula that can tell us which is the next prime number, although there are algorithms that check whether a given natural number is prime. It’s very important these algorithms to be very effective, especially for big numbers.

Overview

As I said each natural number that is divisible only by 1 and itself is prime. That means that 2 is the first prime number and 1 is not considered prime. It’s easy to say that 2, 3, 5 and 7 are prime numbers, but what about 983? Well, yes 983 is prime, but how do we check that? If we want to know whether n is prime the very basic approach is to check every single number between 2 and n. It’s kind of a brute force.

Implementation

The basic implementation in PHP for the very basic (brute force) approach is as follows.

Unfortunately this is one very ineffective algorithm. We don’t have to check every single number between 1 and n, it’s enough to check only the numbers between 1 and n/2-1. If we find such a divisor that will be enough to say that n isn’t prime.

Although that code above optimizes a lot our first prime checker, it’s clear that for large numbers it won’t be very effective. Indeed checking against the interval [2, n/2 -1] isn’t the optimal solution. A better approach is to check against [2, sqrt(n)]. This is correct, because if n isn’t prime it can be represented as p*q = n. Of course if p > sqrt(n), which we assume can’t be true, that will mean that q < sqrt(n).

Beside that these implementations shows how we can find prime number, they are a very good example of how an algorithm can be optimized a lot with some small changes.

Sieve of Eratosthenes

Although the sieve of Eratosthenes isn’t the exact same approach (to check whether a number is prime) it can give us a list of prime numbers quite easily. To remove numbers that aren’t prime, we start with 2 and we remove every single item from the list that is divisible by two. Then we check for the rest items of the list, as shown on the picture below.

The PHP implementation of the Eratosthenes sieve isn’t difficult.

Application

As I said prime numbers are widely used in cryptography, so they are always of a greater interest in computer science. In fact every number can be represented by the product of two prime numbers and that fact is used in cryptography as well. That’s because if we know that number, which is usually very very big, it is still very difficult to find out what are its prime multipliers. Unfortunately the algorithms in this article are very basic and can be handy only if we work with small numbers or if our machines are tremendously powerful. Fortunately in practice there are more complex algorithms for finding prime numbers. Such are the sieves of Euler, Atkin and Sundaram.